Abstract
As scientists and managers seek to understand fire behavior in conditions that extend beyond the limits of our current empirical models and prior experiences, they will need new tools that foster a more mechanistic understanding of the processes driving fire dynamics and effects. Here we suggest that process-based models are powerful research tools that are useful for investigating a large number of emerging questions in wildland fire sciences. These models can play a particularly important role in advancing our understanding, in part, because they allow their users to evaluate the potential mechanisms and interactions driving fire dynamics and effects from a unique perspective not often available through experimentation alone. For example, process-based models can be used to conduct experiments that would be impossible, too risky, or costly to do in the physical world. They can also contribute to the discovery process by inspiring new experiments, informing measurement strategies, and assisting in the interpretation of physical observations. Ultimately, a synergistic approach where simulations are continuously compared to experimental data, and where experiments are guided by the simulations will profoundly impact the quality and rate of progress towards solving emerging problems in wildland fire sciences.
Highlights
As scientists and managers seek to understand fire behavior in conditions that extend beyond the limits of our current empirical models and prior experiences, they will need new tools that foster a more mechanistic understanding of the processes driving fire dynamics and effects
The most practical path to progress in this regard was through the development of point-functional empirical models based on observed correlations between mean fire behavior and environmental and fuel parameters from laboratory and/or field observations [3,4]
As scientists and managers seek knowledge of fire behavior in conditions that extend beyond the limits of our current empirical models and prior experiences, we will need new tools that foster a more mechanistic understanding of the processes driving fire dynamics and their ecological effects
Summary
As scientists and managers seek to understand fire behavior in conditions that extend beyond the limits of our current empirical models and prior experiences, they will need new tools that foster a more mechanistic understanding of the processes driving fire dynamics and effects. Process-based models are processed‐based not more complex descriptive or empirical models; invaluable and effective technique for advancing our understanding of complex systems, across a they differ in that they are designed to mimic the mechanistic behavior of a complex system by range of scientific disciplines (e.g., engineering, meteorology, hydrology, oceanography, soil physics, explicitly and representing the individual known, or assumed, controlling biology).
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